Coherent Bistatic 3D Ultrasound Imaging using Two Sparse Matrix Arrays.

Abstract

In the last decade, many advances have been made in high frame rate three-dimensional (3D) ultrasound imaging, including more flexible acquisition systems, transmit sequences, and transducer arrays. Compounding multi-angle transmits of diverging waves has shown to be fast and effective for 2D matrix arrays, where heterogeneity between transmits is key in optimizing the image quality. However, the anisotropy in contrast and resolution remains a drawback that cannot be overcome with a single transducer. In this study, a bistatic imaging aperture is demonstrated that consists of two synchronized matrix (32 x 32) arrays, allowing for fast interleaved transmits with a simultaneous receive. First, for a single array the aperture efficiency for high volume rate imaging was evaluated between sparse random arrays and fully multiplexed arrays. Second, the performance of the bistatic acquisition scheme was analyzed for various positions on a wire phantom and was showcased in a dynamic setup mimicking the human abdomen and aorta. Sparse array volume images were equal in resolution and lower in contrast compared to fully multiplexed arrays, but can efficiently minimize decorrelation during motion for multi-aperture imaging. The dual array imaging aperture improved the spatial resolution in the direction of the second transducer, reducing the average volumetric speckle size with 72% and the axial-lateral eccentricity with 8%. In the aorta phantom, the angular coverage increased by a factor of three in the axial-lateral plane, raising the wall-lumen contrast with 16% compared to single array images, despite accumulation of thermal noise in the lumen.